curso de mestrado em oncologia - repositório aberto · curso de mestrado em oncologia predictive f...
TRANSCRIPT
Curso de Mestrado em Oncologia
PPrreeddiiccttiivvee FFMMuuccoossiittiiss
iinnffllaammmm
Dissertao de Mestrado da Licenciada
Curso de Mestrado em Oncologia
FFaaccttoorrss ffoorr CChheemmootthheerraappyy--iinn iinn CCoolloorreeccttaall CCaanncceerr PPaattiieenn
mmaattoorryy rreellaatteedd ggeenneess ppoollyymmoorr
Dissertao de Mestrado da Licenciada
Andreia Catarina Dias Rodrigues
Porto, 2008
nndduucceedd OOrraall nnttss:: rroollee ooff
rrpphhiissmmss
eia Catarina Dias Rodrigues
PPrreeddiiccttiivvee FFaaMMuuccoossiittiiss ii
iinnffllaammmm
Dissertao de Mestrado da
Orientador: Prof. Doutor Mrio Dinis Ribeiro
Curso de Mestrado em Oncologia
aaccttoorrss ffoorr CChheemmootthheerraappyy--iinnddiinn CCoolloorreeccttaall CCaanncceerr PPaattiieenntt
mmaattoorryy rreellaatteedd ggeenneess ppoollyymmoorr
Dissertao de Mestrado da Licenciada
Andreia Catarina Dias Rodrigues
Porto, 2008
Orientador: Prof. Doutor Mrio Dinis Ribeiro
Curso de Mestrado em Oncologia
dduucceedd OOrraall ttss:: rroollee ooff
rpphhiissmmss
Andreia Catarina Dias Rodrigues
Orientador: Prof. Doutor Mrio Dinis Ribeiro
Dissertao de candidatura ao grau de Mestre apresentada ao Instituto de Cincias
Biomdicas de Abel Salazar Universidade do Porto
Aos meus pais
minha irm
Ao meu noivo
Por todo o apoio, amor e ateno.
Muito Obrigada!
TABLE OF CONTENTS
TABLE OF CONTENTS
V
ACKNOWLEDGEMENTS .. VIII
OUTLINE OF THE THESIS ... XII
SUMMARY XIV
I. RATIONALE . 1
II. AIM 6
III. BACKGROUND . 8
A. ORAL MUCOSITIS DEFINITION AND ASSESSMENT SCALES 9
B. EPIDEMIOLOGY ... 14
C. CLINICAL COURSE .. 16
D. BIOLOGIC BASIS AND PATHOGENESIS . 20
E. PREDICTIVE FACTORS ... 28
F. MANAGEMENT OPTIONS FOR ORAL MUCOSITIS 46
IV. DESIGN OF STUDY AND SELECTION OF PARTICIPANTS ... 67
A. TYPE OF STUDY AND SELECTION OF PARTICIPANTS ... 68
B. VARIABLES .. 69
C. PROCEDURES AND DATA COLLECTING METHODS 70
D. STATISTICAL ANALYSIS ... 77
V. RESULTS .. 78
VI. DISCUSSION 85
VII. CONCLUSION .. 96
REFERENCES .. XVIII
ADDENDA . XXVIII
ABREVIATIONS LIST XXXVIII
TABLE OF CONTENTS
VI
TABLES INDEX
Table 1. Assessment of Oral Mucositis .. 13
Table 2. Relation between antineoplastic treatment and risk of grade 3-4 oral
mucositis .. 16
Table 3. Candidate polymorphisms and their respective probes 72
Table 4. Primers sequence, cycling conditions and digested fragments for each
of the SNPs analyzed throught PCR-RFLP 73
Table 5. Description of participants and comparison of those with and without
mucositis .. 80
Table 6. Genetic polymorphisms among patients with and without mucositis .. 83
Table 7. TNF- and COX-2 polymorphisms, adjusted for earlier oral mucositis,
among patients with and without mucositis 84
TABLE OF CONTENTS
VII
FIGURES INDEX
Figure 1. Oral Mucositis graded by World Health Organization scale .. 11
Figure 2. The effect of symptoms of oral mucositis on short and long- term
quality of life . 18
Figure 3. A Multiple Mechanism Model of the Pathobiology of Mucositis .. 25
Figure 4. Exemplificative graphic of an allelic discrimination analysis ..... 72
Figure 5. Identification in a 1.5% agarose gel of a 273 bp DNA fragment
containing the -1195G/A COX2 polymorphism . 74
Figure 6. Identification in a 2% agarose gel of a 157 bp DNA fragment
containing the -765G/C COX2 polymorphism ... 74
Figure 7. Identification in a 2% agarose gel of a 164 bp DNA fragment
containing the -174G/C IL6 polymorphism 74
Figure 8. PCR-RFLP analysis of -1195G/A COX2 polymorphism in a 2%
agarose gel 75
Figure 9. PCR-RFLP analysis of -765G > C COX2 polymorphism in a 3%
agarose gel ... 75
Figure 10. PCR-RFLP analysis of -174G/C IL6 polymorphism in a 3% agarose
gel 75
V
ACKNOWLEDGEMENTS
ACKNOWLEDGEMENTS
IX
Ao meu orientador, Prof. Doutor Mrio Dinis Ribeiro, que aceitou colaborar e permitiu a
realizao deste trabalho, e por toda a motivao, pacincia, apoio, ensinamentos e dedicao
inigualveis. Especialmente por acreditar e confiar nas minhas capacidades e no meu trabalho.
Ao Prof. Doutor Carlos Lopes, Director do Curso de Mestrado em Oncologia, pela
oportunidade de frequentar este curso fascinante na rea da Oncologia, desenvolver este
trabalho e pelo auxlio e orientaes concedidas.
Ao Prof. Doutor Rui Medeiros, responsvel pelo Grupo de Oncologia Molecular, por ter
possibilitado a criao das condies necessrias ao desenvolvimento da pesquisa laboratorial
inerente a este trabalho.
Dr. Ana Carina Pereira, biloga pertencente ao Grupo de Oncologia Molecular, por todo o
empenho, dedicao e apoio incansvel. Especialmente pelas horas extra de trabalho e por me
ter ajudado na reviso da parte laboratorial deste documento. Sem a sua colaborao, tudo isto
no teria sido possvel.
Aos professores do Curso de Mestrado em Oncologia, pelos valiosos ensinamentos e o
convvio agradvel proporcionados durante este percurso.
Aos meus colegas de Mestrado, pela amizade e companheirismo durante o curso.
Especialmente mestranda Cludia Patrcia Carvalho, por todos os momentos partilhados,
pelo apoio, aconselhamento, ateno carinhosa dispensada e amizade constante.
Ao Dr. scar Vilo, Director do Servio de Cuidados Paliativos do IPOCFG-EPE, pela
pacincia, compreenso, amizade e auxlio imprescindvel realizao deste trabalho.
ACKNOWLEDGEMENTS
X
Dr. Helena Gervsio, Directora do Servio de Oncologia Mdica do IPOCFG-EPE, por ter
possibilitado a realizao deste trabalho e pela compreenso e apoio concedidos.
Aos oncologistas Dr. Joo Ribeiro, Dr. Paula Jacinto e Dr. Margarida Teixeira, do Servio
de Oncologia Mdica, pela disponibilidade, pacincia, compreenso e motivao
demonstradas. O seu auxlio foi determinante no contacto com o doente oncolgico com
cancro colorrectal.
Ao Dr. Frederico Valido, Director do Servio de Patologia Clnica do IPOCFG-EPE, e a
todos os tcnicos de sade que trabalham neste servio, pela compreenso, disponibilidade,
gentileza e empenho na colheita e armazenamento de especmenes necessrios realizao
deste trabalho. Sem o vosso auxlio, no teria sido possvel.
Ao Sr. Enfermeiro Joo Moreira, Enf. Chefe do Servio de Oncologia Mdica Internamento,
pelo auxlio sempre pronto em qualquer momento, disponibilidade e compreenso
demonstradas e por ter tornado vivel a realizao deste estudo.
Ao Sr. Enfermeiro Carlos Gis, Enf. Chefe do Servio de Oncologia Mdica Hospital de
Dia/Consultas e a todas as Sr.s Enfermeiras que trabalham neste departamento, pela
disponibilidade, auxlio prestado no contacto com o doente oncolgico e ainda pela ateno e
gentilezas concedidas.
s secretrias do Servio de Oncologia Mdica, pela pacincia e ateno tantas vezes
concedida. Especialmente Sr. Fernanda Morais, por todo o trabalho e tempo despendido e
por toda a dedicao.
Aos meus colegas e/ou amigos enfermeiros do Servio de Oncologia Mdica Internamento,
pela motivao, pacincia, compreenso, amizade e companheirismo constantes.
Especialmente pela convivncia durante estes anos e pela fora em todos os momentos.
ACKNOWLEDGEMENTS
XI
A todos os doentes oncolgicos, o foco deste estudo, que espontaneamente concordaram
participar nesta investigao.
A todos aqueles, que mesmo no citados, de alguma forma contriburam para a realizao
deste trabalho.
Por fim, a todos os meus familiares pela compreenso e apoio indispensveis durante toda a
minha vida. Em especial aos meus pais por todos os sacrifcios e por tudo o que fizeram por
mim. minha irm e ao meu noivo por terem sempre acreditado em mim.
X
OUTLINE OF THE THESIS
OUTLINE OF THE THESIS
XIII
In Chapter I, following a shortly reference concerning to colorectal cancer epidemiology
and currently treatments available, including their considerable dose-limiting toxicities, such
as oral mucositis, the motivation and the problem for the thesis will be presented individual
genetic variability as a predictive factors for oral mucositis in colorectal cancer patients
submitted to chemotherapy.
In Chapter II, an announcement of the aim of this study will be made.
In Chapter III, background information will be provided to readers. A review on the
assessment scales, epidemiology, clinical course, pathogenesis, predictive factors and
management options for oral mucositis will be addressed in further detail. Expected genetic
polymorphisms involved in the inflammatory reaction during the evolution of oral mucositis
will be described.
In Chapter IV, type of study, target population, sampling method, characteristics of patients
to be studied, data collecting methods and statistical analysis will be described.
In Chapter V, main results, concerning to participants characterization (clinical predictive
factors) and role of genetic polymorphisms will be presented.
The discussion of main findings and limitations of this research will be made in Chapter VI.
Finally, in Chapter VII, conclusions about this study will be the starting point for needed
future research.
Results from this study were submitted and accepted for oral presentation and publication at
the 16th United European Gastroenterology Week UEGW 2008 (Vienna, Austria).
XIII
SUMMARY
SUMMARY
XV
Oral mucositis induced by chemotherapy is a significant dose-limiting and onerous side effect
of cancer therapy. The pathobiology of oral mucositis is not straightforward being estimated a
role of both local and systemic factors, such as a variable inflammatory response in its
development.
The aim of this research was to establish the role of genetic polymorphisms in genes
modulating the inflammatory response (IL-1, IL-1, IL-1RN, IL-6, TNF- and COX-2) in
the evolution of oral mucositis. From a consecutive series of colorectal cancer patients treated
with chemotherapy and followed at IPOCFG-EPE between February and March 2008
(n=108), cases with mucositis (n=26 (24%), most with oral mucositis graded 1-WHO (55%))
and those without mucositis (n=82 (76%)) were assessed for clinical data using patient
records. Real Time-PCR and PCR-based RFLP techniques were used for genetic
polymorphisms study in DNA samples (extracted from peripheral blood leukocytes).
No differences were observed both in gender, mean age of participants, BMI, diabetes
mellitus, dental prosthesis, smoking, alcohol consumption and hematological data changes
between cases and controls. Previous oral mucositis was reported in a higher proportion of
cases (35%) (vs 0% in controls, p0.001). A allele carriers of -308G>A TNF- (GA and AA
genotypes) have an increased risk for oral mucositis (2.3 95%CI: 0.61-8.67), when adjusted
for earlier oral mucositis. For the remaining polymorphisms assessed no trend was noticed.
In their consecutive series of patients, carriers of -308A allele of TNF- seem to be involved
in the risk for oral mucositis after chemotherapy for colorectal cancer. Further studies with
larger samples should be conducted as this may represent a risk marker for this important
side-effect after chemotherapy, in a way that may enable to submit patients to preventive
strategies. These preventive strategies, such as the previous diagnosis of a genetic
polymorphism related to oral mucositis inflammation, probably reduce its occurrence and
severity on the basis of a specific management and, as a result, improve the patients quality
of life.
XV
RESUMO
RESUMO
XVII
A mucosite oral induzida por quimioterapia caracteriza-se como sendo um efeito secundrio
dispendioso e dose-limitante extremamente importante e inerente ao tratamento da doena
oncolgica. A fisiopatologia da mucosite oral complexa e considera-se o papel de ambos os
factores locais e sistmicos, como por exemplo uma resposta inflamatria varivel, no seu
desenvolvimento.
O intuito desde estudo foi determinar o papel dos polimorfismos genticos nos genes que
medeiam a resposta inflamatria (IL-1, IL-1, IL-1RN, IL-6, TNF- e COX-2) no processo
de evoluo da mucosite oral.
A partir de uma srie consecutiva de doentes oncolgicos com cancro colorrectal submetidos
a quimioterapia e admitidos no IPOCFG-EPE entre Fevereiro e Maro de 2008 (n=108), os
casos com mucosite (n=26 (24%), a maioria com mucosite oral classificada no grau 1 OMS
(55%)) e os doentes oncolgicos sem mucosite (n=82 (76%)) foram seleccionados atravs dos
seus processos, tendo em conta a informao clnica.
As tcnicas de RT-PCR e de PCR-RFLP foram usadas no estudo dos polimorfismos genticos
em amostras de ADN (extradas de leuccitos perifricos).
No foram identificadas quaisquer divergncias entre gneros, idade mdia dos participantes,
ndice de massa corporal, diabetes mellitus, prtese dentria, hbitos tabgicos e alcolicos e
alteraes hematolgicas nos grupos caso e controlo. A mucosite oral prvia foi identificada
numa grande proporo de casos (35%) (vs 0% no grupo controlo, p0.001). Os portadores do
alelo A na posio -308G>A no gene TNF- (gentipos GA e AA) possuem um risco
acrescido para desenvolver a mucosite oral (2.3 95%CI: 0.61-8.67), quando os resultados so
ajustados para a mucosite oral prvia. Relativamente aos restantes polimorfismos estudados,
no foi observada qualquer tendncia.
Em suma, numa srie consecutiva de doentes oncolgicos, a presena do alelo A do TNF- na
posio -308, parece estar relacionada com o risco de desenvolver mucosite oral aps os
tratamentos de quimioterapia especficos para cancro colorrectal. Para que se possam
estabelecer medidas profilticas, sero necessrios estudos ulteriores que incluam amostras de
RESUMO
XVIII
maiores dimenses, uma vez que este polimorfismo poder constituir um factor de risco
determinante no desenvolvimento da mucosite oral aps quimioterapia,. Estas medidas
preventivas, como por exemplo a identificao de um polimorfismo gentico relacionado com
a inflamao na mucosite oral, poder reduzir a sua incidncia e gravidade, atravs da
implementao de estratgias especficas, e consequentemente, melhorar a qualidade de vida
do doente oncolgico.
2
RATIONALE I
I. RATIONALE
2
Truth is a shining goddess, always veiled, always distant,
never wholly approachable, but worthy of all the devotion of
which the human spirit is capable."
[Betrand Russell, 1961]
I. RATIONALE
3
Increasingly, cancer assumes a threat position for the world population, comprising, by this
way, an imperative cause of morbimortality. People adopt western lifestyle behaviors and live
to older ages. As people live more years, aging related diseases, including cancer growths,
will rise and its expected an increase of its prevalence in the first half of the century (Sapeta,
2004).
Cancer victimized 22.711 Portuguese in 2003, and is the second leading cause of death in
Portugal, following heart and cerebrovascular diseases. Colorectal cancer is the first cause of
death related to this pathology, and represents fourteen percent of the total cancer deaths
(INE, 2003).
Worldwide 783.000 new colorectal cancer cases per year are diagnosed and affect
analogously both sexes (about 401.000 new cases in male gender and 381.000 new cases in
female gender). It is estimated that occurs almost 394.000 deaths per year due to this
neoplasia, worldwide. In European Union, colorectal cancer appears as the second leading
cause of death in male of total cancer cases. Worldwide, new colorectal cancer cases
increased prompt and considerably since 1975 (when they were about 500.000) (Boyle et al,
2000).
In the past decade took place significant progress in the treatment of localized colorectal
cancer, due to the advancements occurred in the surgery, radiation therapy and chemotherapy
(Wolpin et al, 2007).
Surgery remains the only therapeutic option capable to obtain the cure for the most part of
colorectal cancer cases. However, chemotherapy and/or radiotherapy may be recommended as
neo-adjuvant or adjuvant therapeutic alternatives. Currently, chemotherapy is responsible for
the improvement of survival in various tumors and has an important role in the cure of cancer,
in the enhancement of life expectancy and in the palliation of symptoms (Costa et al, 2005).
However, these treatments have considerable dose-limiting toxicities, including oral mucositis
(Fadda et al, 2006) and onerous side-effects in cancer treatment (Pico et al, 1998).
Oral mucositis represents a foremost non-hematologic complication of cytotoxic
chemotherapy and radiotherapy associated with considerable morbidity.
I. RATIONALE
4
The incidence and severity of oral mucositis are influenced by the sort of antineoplastic
treatment administered and by patient-related factors. Almost 40% of patients treated with
conventional chemotherapy experience oral treatment-related complications (Kstler et al,
2001). When the only drug administered is 5-Fluorouracil, severe oral mucositis occurs in
approximately 15% of cancer patients (Spencer, 2005). Nevertheless, in polychemotherapy
regimens, the administration of 5Fu combined with Irinotecan and Leucovorin is associated
with rates of severe (grade 3-4) oral mucositis in only 5% (Sonis et al, 2004). In combined
chemotherapy regimen with oxaliplatin-5Fu and Leucovorin, the risk of grade 1 and 2 of oral
mucositis is 16% and 11%, respectively (Ravaioli et al, 2002).
Oral mucositis is related to a variety of acute and chronic symptoms that exert a considerable
negative impact on quality of life. These quality of life complications can endure for 6 months
after the conclusion of antineoplastic treatments. In addition, it is associated with significant
clinical and economic consequences, such as the delay or dose reductions of chemotherapy or
radiotherapy, thus worsening long-term treatment outcomes and likewise the increase of the
duration of hospitalization and the symptoms control needs. A nursing survey, realized in
European countries, found that assessment and management practices for oral mucositis
varied extensively across Europe. So, it is imperative to develop broadly accepted guidelines
for the prevention and management of oral mucositis, in way to promote a standardization of
practices and uniformity of care and increase the quality of care provided to patients (Stone et
al, 2005).
The multifactorial nature of oral mucositis (Fadda et al, 2006), related to patient or his
surrounding environment, has been studied with intend of identify which agents contribute to
its development. These predictive factors can be divided regarding its modifiable capacity.
Those that have a changeable capacity include: oral hygiene (Dodd et al, 2000; McCarthy et
al, 1998), hematological data, body surface area, smoking, alcohol consumption, presence of
dental prosthesis and performance status (McCarthy et al, 1998). On the contrary, factors not
modifiable or particularly difficult to modify comprise: sex (Vokurka et al, 2006), age
(Repetto, 2003), ethnicity (McCollum et al, 2002), diabetes, sociodemographic data, salivary
flow/xerostomia, regimen of cytotoxic drugs, herpes simplex virus antibody titer (McCarthy
et al, 1998), patients diagnosis (Pico et al, 1998), and genetic polymorphisms in the
expression of transcription factors transforming the inflammatory reaction (IL-1, Il-6 e TNF-
) (Kstler et al, 2001).
I. RATIONALE
5
As the pathobiology of oral mucositis is not simple, it is anticipated a role of both global (i.e.
gender, race) and tissue specific factors (i.e. epithelial type, local microbial environment)
(Anthony et al, 2006), such as a changeable inflammatory response in its evolution.
The capacity to predict which patients are at risk of mucositis might become possible.
However, individual variability in toxic mucosal response is almost impossible to predict at
present; but, this might change (Sonis, 2004).
Accordingly, it is relevant the accomplishment of a research with propose of identify which
are the predictive factors of oral mucositis, particularly of biological nature, in colorectal
cancer patients undergone to chemotherapy at IPOCFG-EPE; in way to contribute to the
improvement of an untimely prophylaxis and diagnosis of this toxicity and, as a result, reduce
its occurrence and severity. This research will privilege the role of genetic polymorphisms
transforming the inflammatory reaction (some pro-inflammatory cytokines and, in an original
way, the enzyme cyclooxygenase 2) in the evolution of oral mucositis.
6
AIM II
II. AIM
7
To establish the role of genetic polymorphisms in the expression of transcription factors
transforming the inflammatory reaction (IL-1, IL-1, IL-1RN, Il-6, TNF- and Cox-2) in the
development of oral mucositis associated with chemotherapy in colorectal cancer patients.
8
BACKGROUND III
III. BACKGROUND
9
A. ORAL MUCOSITIS DEFINITION AND ASSESSMENT SCALES
Cancer therapy should result in complete eradication of cancer and spare normal tissues from
toxic effects of therapy. In effect, as new strategies to prevent and/or manage certain therapy-
induced complications emerge, there has been a propensity to increase the strength of the
cancer therapy. However, with the lack of considerable progress relative to the prevention or
treatment of oral complications, there has tended to be an enhanced prevalence of oral tissue
damage (mucositis) and other oral complications resulting from the direct and indirect
stomatotoxic effects of cancer therapies.
The expression oral mucositis emerged in the late 1980s, to explain the chemotherapy and
radiotherapy induced inflammation of the oral mucosa, which represents a separate entity
different from oral lesions with other pathogenic background summarized as stomatitis
(Kstler et al, 2001).
A major difficulty for researchers investigating mucositis has been a lack of an ultimate
technique to appropriately assess oral mucositis (Pico et al, 1998). However, assessment is
indispensable to evaluate the numerous parameters of oral mucositis, including subjective,
objective and functional status (Jaroneski, 2006).
Historically, the expressions stomatitis and mucositis have frequently be used interchangeably
as describing inflammatory oral conditions, therefore, the assessment of the impact of oral
mucositis in clinical trials has been complicated by the lack of consistent terminology
(Peterson et al, 2004). In addition, the data of these clinical trials is usually contradictory due
to the parameters used to assess efficacy of diverse modalities to manage or prevent oral
mucositis induced by cancer therapy (Redding, 2005). Further barriers to routine oral
assessment comprise gaps in knowledge concerning to oral cavity changes associated with
mucositis, absent and sporadic oral evaluation, failure to use a consistent assessment tool,
inadequate documentation and discrepancy in using assessment data to guide clinical practice
(McGuire, 2003 cited by Jaroneski, 2006).
The need to evaluate a number of probable new therapeutic options and the importance of
measuring treatment-related morbidity and mortality, has motivated the development of new
assessment scales, validated and universally accepted (Pico et al, 1998; Peterson et al, 2004).
III. BACKGROUND
10
If possible, a mucositis scoring system should be objective, validated and reproducible (inter-
user/intra-user reliability) across all clinical situation and applications. The scale should be
amply sensitive to assess suitable parameters of the mucositis experience consistently across
different treatment modalities, including cancer chemotherapy, radiotherapy and
chemoradioterapy. In addition, it should accurately measure elements related with mucositis
consistently (i.e., content validity) by reviewing the pertinent literature and soliciting the
opinions and ideas of experts in the field. It also should be indispensable a minimal training to
produce systematic and precise results, and the scale should be characterized by intrarater and
interrater reliability, which is the same that demonstrating the reproducibility of the scoring
when used by the same person and/or by different individuals over a defined period of time
(Pico et al, 1998; Sonis et al, 2004). No scale established to date meets all these criteria or is
accepted universally (Sonis et al, 2004). As a result, because the importance of explain
accurately, classify objectively, determine reproducibly the severity of mucosal injure and
link anatomic changes to clinically pertinent outcomes, a number of different scoring systems
have been developed (Sonis et al, 2004; Peterson et al, 2004). These can be separated into
three types: general or gross variable measurement scales; multiple mucositis component
variable assessment scales; and physiologic or laboratory evaluation schemes (eg,
thermography or exfoliated mucosal cells) (Peterson et al, 2004). It may be complicated to
propose one only scale for assess mucositis that will be suitable in all clinical situations,
because of the assortment of chemoradiotherapy treatments existing and their resulting
toxicities (Pico et al, 1998). Oral mucositis scales vary considerably in their complexity and
have undergone unreliable degrees of validation. These tools were designed to describe in
global terms stomatotoxicity resulting from diverse cancer treatments. Oral mucositis scales
consist of four-point or five-point scales that rate generally the status of the mouth relative to
the clinically observed mucosal appearance, severity of patient pain, and, in some instances,
the patients functional abilities relative to his or her oral status (Sonis et al, 2004). Similar
descriptive terms are used in all of the scales; but, there are slight differences which avoid
interchangeably. The discrepancies between scales subsist in the measurement of the patients
pain and in the assessment of the impact of mucositis on the patients capability to eat.
Furthermore, a lack of agreement exists concerning the score attached to a specific sign or
symptom complex. All of these factors, as well as the terminology used to describe signs of
mucositis, supply to making comparisons between the scales complex (Pico et al, 1998). In
addition, the facility to evaluate results between studies is delayed by the use of different
scales (Avritscher et al, 2004; Belim et al, 2002; Cella et al, 2004; Sonis et al, 1999, cited by
Jaroneski, 2006). Historically, many of these simple, combined, variable toxicity scales have
III. BACKGROUND
11
been based on a scale developed by the World Health Organization (WHO) for the clinical
assessment of patients receiving cancer therapy. A number of analogous scales have been
developed and promoted as part of the National Cancer Institute-Common Toxicity Criteria
(NCI-CTC) scales, which are used regularly by cooperative oncology groups and oncology
researchers (Sonis et al, 2004), and were designed to reveal toxicities related to particular
chemotherapeutic agents or regimens (Jaroneski, 2006).
Sonis et al. (1999), mentioned by Jaroneski (2006), sought to design, test, and validate a
scoring system, the Oral Mucositis Assesment Scale (OMAS), that was easy to use and that
clinical assessment of oral mucositis took less than five minutes to complete. The OMAS has
been revealed to be extremely reproducible between observers, responsive over time and to
accurately record the elements considered to be related to mucositis. This tool provides an
objective evaluation of oral mucositis based on scoring the extent of
ulceration/pseudomembrane (score 0 to 3) and erythema (score 0 to 2) on the maxilarllary and
mandibular labial mucosa, right and left ventral and lateral tongue, floor of the mouth, soft
palate/fauces and hard palate. The revised oral mucositis staging system of the Western
Consortium of Cancer Nursing Research (WCCNR scale) also measures anatomic changes
associated with oral mucositis, and is based on three descriptors (lesions, erythema, and
bleeding) and is scored on a scale from 0-3. This staging system has numerous advantages
over other tools for assessing mucositis related to chemotherapy, radiotherapy, or both,
because it evaluates and stages only mucositis and is rapid and simple to use through clinical
nursing practice (Peterson et al, 2004; Jaroneski, 2006). The Oral Mucositis Index assesses
the severity of mucositis in terms of erythema, ulceration, atrophy and edema (each graded on
a scale of 0 to 3). This tool has been shown to be internally reliable with high test-retest and
inter-rater reliability and strong support of construct validity (Peterson et al, 2004).
The World Health Organization Oral Toxicity Scale measures anatomic, symptomatic and
functional components of oral mucositis. Severity is graded from 0 (no mucositis) to 4
(alimentation not possible and the patient needs parentral feeding).
Figure 1. Oral Mucositis graded by World Health Organization scale (adapted from WHO, 1979)
III. BACKGROUND
12
The National Cancer Institute Common Toxicity Criteria provides a rating of the severity of
oral mucositis on a scale of 0 (none) to 4 (most severe) and has been shown to provide an
effective measure of the toxicity of treatment by evaluating the clinical findings of mucositis
and functional consequences of mucositis in two distinct scales. Although an update NCI-
CTC scale (Common Terminology Criteria for Adverse Events, version 3.0) was released in
October 2003, widespread implementation will take time (Peterson et al, 2004; Sonis et al,
2007).
The most frequently used scales are the WHO scale (utilized in 38% of studies) and the NCI-
CTC scales (utilized in 43% of trials) and it appears that these tools will remain standards for
the immediate future (Redding, 2005), because, as noted previously, symptoms, signs and
functional disorders are assessed, and a global score is completed enthusiastically (Sonis et al,
2004).
A second group of scales has developed out of these simple scales, and evolved as nursing
management and clinical research tools. These can be characterized as using an arrangement
of objective, functional and symptomatic variables. Like the simpler toxicity scales, the oral
mucositis scales combining objective, functional and symptomatic descriptors concern them
to specific anatomic areas, adding greater specificity with a range of aspects of oral function
and subjective patient responses (Sonis et al, 2004, Jaroneski, 2006). A lot of these scales
include holistic elements that are not conventionally considered directly associated with
mucositis (Stone et al, 2005; Jaroneski, 2006).
A third series of scales, the detailed objective scoring scales, were designed for clinical
research trials and are liable to focus on directed, separately scores, objective and subjective
end points (Sonis et al, 2004), and normally oblige the training of specialized oral cavity
experts to supply accuracy and consistency in mucositis evaluation (Pico et al, 1998). The
clinical qualifications of the assessor appear to be less important, eventually, than training and
experience with using the scale (Sonis et al, 2004). Accurate monitoring and measurement of
oral mucositis is crucial to its successful management. The wrong use of these scales can
result in errors in estimation of the severity of the condition (Stone et al, 2005).
There is disagreement about require for the use of added objective scales in clinical trials.
Some investigators feel that assessment of intraoral tissues is critical for an accurate
assessment of mucositis severity; on the other hand, others feel that patient symptoms are the
only importance parameters to assess and that tissue changes are not significant.
III. BACKGROUND
13
Table 1. Assessment of Oral Mucositis
Scale (use) Source Elements measured Advantages Disadvantages Simple, combined-variable mucositis scoring scales
NCI-CTC (clinical and research) Trotti et al, 2000 http://ctep.cancer.gov
Combined elements: symptom (pain), signs (erythema, ulceration); function: type of dietary intake
Used widely in research and clinical care settings; specific scales for mucositis in patients undergoing head/neck radiation, chemotherapy, or HSCT
Research assessment potentially confounded by combination or symptoms, signs, and functional changes
WHO (clinical and research) WHO, 1979 Combined elements: symptom (pain), signs (erythema, ulceration); function: type of dietary intake
Used widely in research and clinical care settings; specific scales for mucositis in patients undergoing head/neck radiation, chemotherapy, or HSCT
Research assessment potentially confounded by combination or symptoms, signs, and functional changes
RTOG (clinical and research) RTOG (see http://www.rtog.org/members/toxicity/acute.htm)
Combined elements: symptom (pain), signs (unspecified); function: unspecified
Used widely in research and clinical care settings
Research assessment potentially confounded by combination of symptoms, signs, and functional changes
Detailed, objective mucositis scoring scales
OMI for HSCT (research) Schubert et al., 1992 Thirty-four mucosal changes: signs (atrophy, erythema, ulceration/ pseudomembrane edema, and selected sites); pain scores (separate VAS)
Specific to 11 oral anatomic sites, thereby permitting subanalyses of changes across the oral mucosa; eliminates confounders of symptoms and functional disturbances, cores consistent with NCI and WHO scores
Requires more examiner experience and time than NCI-CTC and WHO scales; only tested in patients undergoing HSCT
Twenty-item OMI for HSCT (research)
McGuire et al., 2002 Twenty mucosal changes: signs (atrophy, erythema, ulceration/ pseudomembrane edema, and selected sites)
Specific to nine oral anatomic sites; clinical objective changes scored as in full OMI
Requires less expertise than OMI
OMAS for chemotherapy, radiation, and HSCT (research)
Sonis et al., 1999 Signs(erythema, ulceration) Same advantages as OMI with fewer oral anatomic sites scored
Requires more examiner experience and time than NCI-CTC and WHO scales but less time than OMI
Spijkervet Radiation Mucositis Scale (research)
Spijkervet, 1989 White discoloration, erythema, pseudomembrane ulceration
Permits objective measure of tissue injury
Detailed mathematical calculation required; requires further validation in multicenter setting
Combined objective/functional/ symptom scales
Oral Assessment Guide (clinical) Eilers et al. (1988) Signs (erythema), symptoms (pain, salivary changes), functional disturbances (swallowing, voice)
Global scale that can reflect clinical status/outcomes; suitable for nursing care decision making
Not all variables necessarily link with clinical status; some variables not continuous
Western Consortium for Cancer Nursing Scale (clinical)
Western Consortium for Cancer Nursing Research, 1991
Lesions, color, bleeding, subjective variables
Global scale that can reflect clinical status/outcomes; refined in 1998, based on elimination of five measures other than lesions, color, or bleeding
Mixed objective, subjective, and functional variables; difficult to score precisely
Walsh Quantitative Scoring System for Oral Mucositis (clinical and research)
Walsh et al., 1999 Mucosal changes, functional changes, salivary function, pain
Conceptual elements of NCI or WHO scale applied to specific anatomic sites; moderate training
Not validate; only tested in HSCT patients
Tardieu Quantitative Scale of Oral Mucositis for HSCT (research)
Tardieu et al., 1996 Mucosal changes, salivary function, function (voice, swallow), pain
Includes four anatomic sites, range of severity
Not validated (pilot study only); only tested in HSCT patients; detailed, requires moderate to significant training
Daily Mucositis Scale for HSCT (research and clinical)
Donnelly et al., 1992 Erythema, oral edema, pain, dysphagia
Global scale that can reflect clinical status/outcomes; less detailed than most
Validation in multicenter study needed
MacDibbs Mouth Assessment (research and clinical)
Dibble at al., 1996 Patient symptoms, ulcerations, erythema/hyperkeratosis, sputum smear/ herpes simplex virus culture
Ease of administration generalized assessment (not oral site-specific)
Only reported for radiation mucositis; not validated (pilot study only)
In vitro measurement Epithelial Viability Scale (research)
Wymenga et al., 1997 Trypan blue-based exclusion, based on oral epithelial smears
Easily administered; in vitro objective measure; studied with both chemotherapy-induced and radiation- induced mucositis
Early in development; requires additional validation
NCI-CTC: National Cancer Institute Common Toxicity Criteria; HSCT: hematopoietic stem cell transplantation; WHO: World Health Organization; RTOG: Radiation Therapy Oncology Group, VAS: visual analog scale; OMI: Oral Mucositis Scale; OMAS: Oral Mucositis Assessment Scale.
III. BACKGROUND
14
Subjective assessment may give a correct evaluation of patient function, however, do not take
into account the potential for oral organism to cause systemic infection in the course of the
oral tissue damage related to mucositis. Consequently, objective assessment may be more
imperative than some investigators realize (Redding, 2005).
The regularity with which mucosal health needs to be measured is a function of the objective
of the examination (Sonis et al, 2004). Historically, no agreement has been reached among
experts concerning a universal standard of oral care for patients with cancer regarding the use
of evaluation tools and frequency of mucosal assessment (McGuire, 2003 cited by Jaroneski,
2006). Comparable to other aspects of physical examination, sensivity and accuracy are
frequently a function of the circumstances under which the assessment takes place.
Examination conditions are an issue of practicality, because if the examiner cannot perform
an ample visual assessment of the area to be examined, then results will be compromised. The
expediency and comfort of both, the examiner and the patient, through the examination can
influence the quality of the overall examination results. A lot of scoring systems have not
compensated for instances in which a patient cannot be observed because of compromising
conditions (haemorrhage, pain, nausea, need of orotracheal intubation, pseudomembranous
candidiasis or topical oral care therapies). While, in some cases, the clinical situation could be
a direct extension of the severity of the oral mucositis, whereas at other times it may be
unrelated (Sonis et al, 2004).
In the absence of generally accepted guidelines for oral mucositis, there are considerable
inconsistencies in the manner that this side effect is assessed and managed (Stone et al, 2005).
Therefore, these inconsistencies do not permit comparisons between patients with oral
mucositis and the probable new strategies found in research could not be used unanimously
and this influence their quality of life.
B. EPIDEMIOLOGY
Mucositis is one of the most recurrent adverse effects in patients receiving high-dose
radiotherapy and/or chemotherapy for cancer and is the second most frequent dose-limiting
factor in patients receiving some chemotherapy drugs (Peterson et al, 2004), but some authors
(Brown and Wingard, 2004 cited by Stone et al, 2005) acknowledged oral mucositis as a
major dose-limiting toxicity in cancer therapy.
III. BACKGROUND
15
The cancer patient risk of developing oral mucositis is extremely variable (Redding, 2005) as
the incidence of this toxicity, which varied significantly among diverse treatment regimens
and modalities for different types of cancer (Peterson et al, 2004; Sonis et al, 2004). The
majority of data supporting the computation on incidence of mucositis are resulting from
clinical trials of chemotherapy and radiation therapy regimens in which the reporting of
mucositis is a secondary objective. For estimates of incidence, no more than grade 3 and 4
mucositis are accounted, because grades 1 and 2 mucositis are not reported evenly in clinical
trials of chemotherapy (Sonis et al, 2004).
There is a relation between cancer diagnosis and risk of grade 3-4 oral mucositis (Sonis et al,
2004). Severe oral mucositis occurs in about six percent of patients with colorectal cancer,
and in patients with rectal cancer it is over eight percent (Sonis et al, 2004). A few degrees of
mucositis occur in about 40 percent of patients who receive cancer chemotherapy (Sonis,
1998), but the occurrence of oropharyngeal mucositis can range from 30% to 75% (Wilder-
Smith et al, 2007), depending on the chemotherapeutic regimen (Napeas et al, 2007).
Although less widespread, oral mucositis also occurs to derived to chemotherapy for a range
of solid tumors (Sonis et al, 2004). With conventional chemotherapy including anthracycline-
based regimens, taxane-based regimes and platinium-based regimens, severe oral mucositis
occurs in 1 to 10 percent of patients, but this can go above 66 percent when these agents are
combined with 5 fluorouracil (5-FU) (Redding, 2005; Sonis et al, 2004). Nevertheless,
administration of 5-FU, with or without leucovorin, is associated with oral mucositis in as
much as 40% of patients (Rubenstein et al, 2004). Severe (grade 3-4) oral mucositis
approaches 10-15% among 5-FU recipients (Redding, 2005; Rubenstein et al, 2004; Sonis et
al, 2004).
For patients with advanced colorectal cancer, the risk of grade 1 2 oral mucositis is 27 %
and 11 %, respectively, in combined chemotherapy regimen with oxaliplatin-5FU
(Tournigand et al, 2006). The administration of Irinotecan, combined with 5FU and
Leucovorin (Folfiri), was associated with rates of severe oral mucositis (grade 3 4) in over 5
percent. The addition of radiotherapy to 5-FU- based regimes may enhance the risk of grade 3
4 oral mucositis in further than 30% (Sonis et al, 2004). The conditions incidence is
consistently higher among patients undergoing for continuous infusion therapy for colon
cancer (Sonis, 1998).
III. BACKGROUND
16
Table 2. Relation between antineoplastic treatment and risk of grade 3-4 oral mucositis
Risk of Grade 3-4 oral mucositis
Regimen No. of studies No. of patients % 95% CI
Mon
oth
erap
y
5-FU 5 1615 2 1-3
5-FU CI 3 146 14 10-18
5-FU/leucovorin 21 3177 14 12-15
5-FU CI + XRT 1 84 6 1-12
Mayo - - 18 -
Roswell Park - - 1 -
Irinotecan 4 409 2 1-4
Pol
yche
mot
her
apy
5-FU/other misc drugs 5 543 6 4-8
5-FU CI/other misc drugs 7 213 12 8-17
Irinotecan/5-FU 3 524 3 1-4
Irinotecan/5-FU/leucovorin 5 318 5 3-8
Oxaliplatin/5-FU/leucovorin - - 2 -
95% CI: 95% confidence interval; 5-FU: 5-fluorouracil; XRT: radiotherapy; CI: continuous infusion; misc: miscellaneous. Source: Risk measures based on reports of clinical antineoplastic therapy.
C. CLINICAL COURSE
Moderate or severe mucositis can have considerable clinical and economic consequences,
posing a grave burden for patients and health care providers (Peterson et al, 2004; Sonis et al,
2004) and it can significantly complicate de management of cancer (Redding, 2005).
Mucositis usually appears between 7 to 14 days following the beginning of chemotherapy or
radiation therapy (Redding, 2005; Napeas et al, 2007), and slowly resolves unless
complicated infection or repeated drug administration (Loprinzi et al, 1995 cited by Cheng,
2007). DeMoor and colleagues (2007), noted that standard mouth sore scores peaked by day
40 (cycle 2), and that patients who reported any symptoms of mouth sores by day 21 (cycle 1)
were five times more likely to develop severe mucositis by day 126 than patients who
reported no symptoms.
III. BACKGROUND
17
Oral and gastrointestinal symptoms
Patients encounter particular oral dysfunction in relation to oral mucositis shared with no
other cancer treatment associated complications (Cheng, 2007).
The suffering caused by oral mucositis is multifaceted (Rose-Ped et al, 2002 cited by Cheng,
2007). Oral mucositis is related with a variety of acute and chronic symptoms that exert a
considerable negative impact on quality of life (Stone et al, 2005; Sonis, 2004). The first signs
and symptoms of oral mucositis comprise edema and erythema, a burning sensation and an
increased sensivity to hot or spicy food. Erythematous areas may expand into eminent white
desquamative patches and consequently into painful ulcers - ulceration (Kstler et al, 2001;
Wilder-Smith et al, 2007; Sonis et al, 2007), which can lead to secondary infection (Napeas
et al, 2007).
Patients can experience functional difficulties in eating, drinking, swallowing and speaking,
because of the mouth sores and the associated serious pain and discomfort (Bellm et al, 2000;
Rose-Ped et al, 2002; Borbasi et al 2002; cited by Stone et al, 2005; Peterson et al, 2004).
Additionally, they can experience changes in food tastes and dry mouth, which are the most
frequent associated problems with oral mucositis. These symptoms have a negative impact on
patients daily living and functioning (Cheng & Chang 2003, Ohrn & Sjoden 2003, Shih et al,
2003 cited by Cheng 2007). Dysphagia and difficulty in swallowing (though less common),
were reported as the most severe and highly distressing problems when present (Cheng,
2007). Symptoms described above should receive the same attention as the mucosal damage
and infections (Garfunkel, 2004; Kwong, 2004 cited by Cheng, 2007).
Psychological effects
Oral mucositis is also liable for patients increased depression (reported in 38% of cancer
patients with changes in oral cavity), sleep disturbances and a significant increase in mood
disturbance (Rose-Ped et al, 2002; cited by Stone et al, 2005), for the reason that oral
dysfunction can have an intense effect on the psychological well-being of the patients with
cancer (Comeau et al, 2001; Dodd et al, 2001; Shih et al, 2003 cited by Cheng, 2007). In
addition, fatigue is more frequent during cycles with mucositis than in cycles without this side
effect (Sonis et al, 2004).
III. BACKGROUND
18
These quality of life complications can keep on for six months following the conclusion of
cancer treatment (Epstein et al, 2001; cited by Stone et al, 2005). As a result, mucositis can be
clinically debilitating, and can drastically reduce quality of life (Rosen et al, 2006; Wilder-
Smith et al, 2007).
The levels of oral functional injury and distress in reply to oral mucositis are not meticulously
assessed and investigated; for the reason that research has not been conducted to verify the
individuals perception and opinion on the intensity of oral dysfunction and the impact on
their lives (Cheng, 2007). Cheng and partners (2007), established that the oropharyngeal
mucositis quality of life scale was effective in demonstrating that usually stomatotoxic
chemotherapy or chemoradiation regimens were associated with a poorer quality of life,
particularly with respect to symptoms, swallowing, and diet.
Hospitalization
Oral mucositis increases the duration of hospitalization, because constant eating difficulties
due to severe pain can lead to weight loss and malnutrition, anorexia, cachexia and
dehydration, leading to patients require for alimentation support (fluid replacement, liquid
diet, and total parenteral nutrition) during this period (Redding, 2005; Peterson et al, 2004;
Elting et al, 2003; cited by Stone et al, 2005; Sonis et al, 2007). In addition, increased
Figure 2. The effect of symptoms of oral mucositis on short and long- term quality of life (adapted from Stone et al, 2005)
III. BACKGROUND
19
hospitalization and feeding tube placement are necessary more frequently for patients who
receive radiation therapy and experience severe oral mucositis (Redding, 2005). Among
patients receiving standard-dose chemotherapy regimens, 70% of them with grade 3-4 oral
mucositis need feeding tubes to preserve satisfactory nutrition, and 62% of patients require
hospitalization (Sonis et al, 2004). Deprived nutritional status may interfere with mucosal
regeneration by decreasing cellular migration and regeneration thus compounding the
problem of oral mucositis (Shih et al, 2003 cited by Cheng, 2007).
Costs
The amount of increased resource utilization correlates with oral mucositis harshness. An
increase of one unit in the World Health Organization (WHO) oral mucositis severity grade
has been shown to correlates with 2,7 supplementary days of total parenteral nutrition, 2,6
further days of injectable narcotic analgesia, 2,6 additional hospital days and 21,000
(US$25,400) in additional hospital charges (Sonis et al, 2001; cited by Stone et al, 2005). In
general, oral mucositis has been associated to result in a mean increase of 35,000
(US$42,700) in hospital charges per patient (Sonis et al, 2001; cited by Stone et al, 2005).
Mucositis has been shown to considerably get longer hospital stays and increase the use of
resources resulting in improved costs for patients receiving chemotherapy for solid tumors
(Redding et al, 2005), however, the financial implications of mucositis (grade 3-4) have been
reported only rarely (Sonis et al, 2004).
Patients who become neutropenic, generally treated with myelosuppressive chemotherapy,
and develop severe mucositis are at seriously increased risk of infection for the spread of oral
organisms, through oral ulceration due to the breakdown of the mucosal barrier, into the
systemic circulation, resulting in life-threatening systemic infection (antibacterial, antifungal
and antiviral use) and also increased mortality (Redding, 2005; Peterson et al, 2004; Brown
and Wingard, 2004; Elting et al, 2003; Epstein et al, 2003; cited by Stone et al, 2005; Sonis et
al, 2007). Mucositis doubles the risk of infection in myelosuppressed patients and quadruples
the risk of infection-related death (Elting et al, 2003 cited by Sonis, 2007). Among patients
with solid tumors who receive myelosuppressive chemotherapy, infection occurs during 73%
of cycles complicated by mucositis, but through only 36% of cycles with analogous
myelosuppression without mucositis (Sonis et al, 2004). A retrospective study of 599 patients
undergoing myelossupressive chemotherapy found that oral mucositis was related with a
III. BACKGROUND
20
number of severe clinical consequences such as bleeding and infection, which frequently
required hospital care. The mean duration of hospital stay was four days for those who did not
have mucositis and six days in those with oral mucositis. This study highlights the grave
burden that even moderate mucositis places on patient and the need for management of the
clinical consequences and consequent impact on health care funds (Peterson et al, 2004).
Mucositis can also interfere with cancer therapy by requiring dose adjustments or treatment
interruption. In approximately 35% of patients with grade 3-4 mucositis, the following cycle
of chemotherapy is delayed; the doses of chemotherapy are reduced in about 60% of patients,
and the regimen is discontinued in approximately 30% of patients (Sonis et al, 2004). It could,
consequently, have a negative impact on treatment outcome because failure to deliver planned
doses of chemotherapy or use of low-dose chemotherapy are associated with poorer outcomes
in malignant diseases and can compromise cure rates and increase mortality (Kwong et al,
1997; Cox et al, 1992; Fowler and Lindstrom, 1992; Bonadonna et al, 2005; Maciejewski et
al, 1989; cited by Stone et al, 2005; Redding, 2005; Rosen et al, 2006; Peterson et al, 2004;
Wilder-Smith et al, 2007; Sonis et al, 2007).
Accordingly, oral mucositis can have significant psychological and physical effects on cancer
patients, which interfere with their quality of life. Furthermore, it increases costs with
additional treatments and the duration of hospitalization, and can also interfere with cancer
therapy.
D. BIOLOGIC BASIS AND PATHOGENESIS
The complex pathobiology and molecular mechanisms underlying mucositis have been
appreciated only in recent times. Our understanding of the cellular, molecular, and tissue
events that lead to this cancer therapy toxicity, continue to progress (Peterson et al, 2004;
Sonis et al, 2004). Historically, mucositis was viewed only as an epithelium mediated event
that was the effect of the nonspecific toxic effects of radiation or chemotherapy on dividing
epithelial stem cells. It was believed that the direct inhibitory effects of cancer therapies on
DNA replication and mucosal cell proliferation layer led to loss of the regeneration capacity
of the epithelium. This results in epithelial thinning as no new cells are being developed at the
basal layer and existing cells migrate to surface and are exfoliated. As more layers of cells are
lost, the epithelium will become thinner and thinner, resulting in erythema initially,
clonogenic cell death, atrophy and ensuing ulceration. Furthermore, it was believed that the
III. BACKGROUND
21
process was facilitated by trauma and oral microorganisms. Chemotherapy causes basal cell
damage when the drugs permeate to these cells from the blood vessels of the submucosal
connective tissue. The high rate of cellular replication makes the oral mucosa particularly
vulnerable to this cytotoxicity. A role for saliva-borne chemotherapeutic agents in the
initiation of mucositis has been proposed, as well, but not established. Chemotherapy-induced
mucositis can be further compounded by simultaneous myelosuppression (Pico et al, 1998;
Redding, 2005; Sonis et al, 2004). This direct, rather linear process failed to account for some
latest findings about the role of others cells and the extracellular matrix in the submucosal
region. These observations indicate that the mechanisms that results in mucositis are not so
straight or simple (Sonis et al, 2004).
Even though the clinical symptoms of mucositis are mainly the consequence of epithelial
damage, the condition itself is the result of a dynamic sequence of biological events that take
place all through the different cellular and tissue compartments of the mucosa. So, mucositis
is not just an epithelial process comes from investigate the relation involving proinflammatory
cytokines and mucosal toxicity in animal and human studies (Sonis et al, 2004). Mucositis is
often erroneously typified as an inflammatory disorder. Nevertheless, results of histological
studies are not reliable with this theory. In fact, leukocytic infiltrates are normally seen
through later stages of the process and are linked with the ulcerative phase of mucositis.
Improved peripheral blood levels of tumor necrosis factor-alpha (TNF-) and interleukins 1
and 6 (IL-1 and IL-6) correlate with the amount of nonhematologic toxicities in patients
following chemotherapy, especially with severity of oral mucositis. Equally, mucosal levels
of IL-1 and gene expression of TNF- are associated with the improvement of mucositis in
animal models. Agents recognized to attenuate the expression of both cytokines, have
established efficacy in the prevention of both experimental and clinical mucositis. Increasing
direct and indirect experimental evidence supports the theory that virtually all the cells and
tissues of the oral mucosa, as well as the extracellular matrix, contribute to barrier damage.
The succession of cell and tissue changes further implies that nothing occurs within the
mucosa as a biologically isolated event. Slightly, it appears that interactions between the
diverse mucosal components, collectively lead to mucositis (Redding, 2005; Sonis et al,
2004).
It has become evident that there is no ubiquitous mucosal reply to antineoplastic treatment. It
is not unusual for dissimilar mucosal types to exhibit differences in the incidence, severity
and course in response to chemotherapy challenges in the same patient (Anthony et al, 2006).
The movable nonkeratinized mucosa of the soft palate, cheeks and lips, the lateral and ventral
III. BACKGROUND
22
surface of the tongue and the floor of the mounth/buccal mucosae are most susceptible to
direct stomatotoxicity, while the gingival, dorsal surface of the tongue or the hard palate are
not often affected, maybe due to their slower rate of cellular turnover (Kstler et al, 2001;
Sonis et al, 2007). There are biological controllers and mediators exclusive to mucosal types
that take part in this type of specificity. It is extremely possible that the local tissue
environment plays a part in affecting mucosal reply to radiation therapy and chemotherapy.
Apoptotic cell death is an important part of mucosal damage. Mucosal tissues vary among
each other, and even within themselves, with respect to their susceptibility to apoptosis (a
variation that impacts on the likelihood of mucositis) (Anthony et al, 2006). Oral lesions tend
to recur in the same location in each experience of mucositis, and these lesions generally
disappear without scar development, except if mucostis is complicated by severe infection or
xerostomia. Nevertheless, other oral squeals of chemotherapy such as epithelial hyperplasia
and dysplasia, as well as glandular and connective tissue relapse, may persist (Kstler et al,
2001).
Sonis (2004/2007) proposed a pathophysiologic mechanism, which includes a cascade of
destructive and inflammatory events initiated by cytotoxic agents and exacerbated by the
presence of systemic and local factors. It is becoming clear that the development of oral
mucositis is a dynamic process and, for descriptive purposes, mucosal barrier damage can be
viewed as having five phases: initiation, up-regulation with generation of messengers/primary
damage response, signaling and amplification, ulceration with inflammation and healing. This
model of injury is established best in oral mucosa than in the rest of the gastrointestinal tract.
Although the model as described seems linear, damage occurs very promptly and concurrently
in all tissues. The stages of this model will be described below.
Initiation
Whatever the target tissue, production of oxidative stress and reactive oxygen species (ROS)
by radiation or chemotherapeutic agents appears to be the primary initiators in a cascade of
complimentary events contributing to oral mucositis. These cancer therapies do cause DNA
strand breaks and secondary direct basal cellular damage. Whether they are generated by
radiation exposure or chemotherapy, ROS directly injure cells, tissues and blood vessels. The
results of studies have shown that ROS are always produced when stomatotoxic agents are
applied. Furthermore, drugs that block or scavenge oxygen free radicals have been shown in
several cases to decrease mucosal injure from the same agents. The activation of ROS also
affects other tissues; in addition to causing direct epithelial tissue injure, to stimulate a
III. BACKGROUND
23
number of transcription factors in successive phases. Although there is death of several cells
within the basal and suprabasal epithelium, it is the obliteration of the cells in the underlying
submucosa that makes the main contribution to damage (Denham and Hauer-Jensen, 2002
cited by Sonis, 2004). The mucosa seems to be absolutely normal at this stage, but the
biological chaos is taking place.
Up-regulation and generation of messenger signals
Several events occur concurrently through this phase. ROS cause DNA injure and consequent
clonogenic cell death in the epithelial layer, but these event is insufficient to report for the
degree of oral mucositis observed. Of the transcription factors activated by ROS and DNA
strand break, nuclear factor-k (NF-k) appears to be the most important because has several
characteristics, such as its possible influence in the expression of up to 200 genes, that
propose that it could be a key element in the origin of mucositis. It is activated by either
chemotherapy or radiation therapy, the 26S proteasome is detectable in stressed mucosa and
results in upregulation of many genes that lead to the production of a group of
proinflammatory cytokines including tumor necrosis factor (TNF-), Interleukin 1 (IL-1)
and Interleukin 6 (IL-6). This leads to tissue damage and apoptosis. Up-regulation of
supplementary genes causes the expression of adhesion molecules, ensuing activation of the
ciclooxygenase-2 pathway and subsequent angiogenesis. Added activity not associated to
DNA changes directly can lead to mucosal injure. In addition, chemotherapy and radiation
therapy hydrolyze the cell- membrane lipid sphingomyelinase or ceramide synthase, which
activates the ceramide pathway leading to apoptosis. Macrophages are activated by
fibronectin breakup and this leads to stimulation of matrix metalloproteinases, which cause
direct tissue damage or an improved production of TNF-. The end result of this phase of
mucositis is one of simultaneous events in all implicated tissues at all levels.
Signaling and amplification
As the mucositis development continues, as well to exerting a direct injurious outcome on
mucosal target cells, proinflammatory cytokines also play an indirect role in amplifying
mucosal damage initiated by chemotherapy and radiotherapy. TNF- activates the ceramide
and capase pathways leading to tissue injury and activates the transcription pathway mediated
by NF-k. In a feedback loop, these processes results in increased production of TNF-, IL-
1, IL-6. In addition TNF- and IL-1 activate matrix metalloproteinases leading to direct
tissue damage, as described earlier. The eventual result of this stage is that the tissue is altered
III. BACKGROUND
24
biologically; even though the clinical appearance of the mucosal surface remains deceptively
normal, because the injurious events are focused in the submucosa and basal epithelium.
Ulceration
All earlier metabolic activity finally results in tissue ulceration, which is the most significant
phase for the patient, as severe pain compromises function. Oral mucositis, particularly that
induced by radiation therapy, commonly is referred to as an inflammatory process, even
though an acute inflammatory infiltrate is not identifiable histologically in the early phases of
radiation-induced mucositis. In addition, stomatotoxicity occurs during periods of greatest
myeloablation in patients treated with chemotherapy. In response to rising doses of radiation
has been reported around cell infiltrate, comprised mainly of reparative RM3/1 positive
macrophages. This infiltrate probably is the result of a series of events activated by oxidative
stress, mediated by activated T cells, and headed by the production of adhesion molecules.
The presence of these cells could represent a meddled antiinflammatory reaction. The
ulcerative stage of mucositis is described as a vigorous inflammatory infiltrate included of
both polymorphonuclear and round inflammatory cells. As these patients are frequently
neutropenic, ulcerated mucosa permits ingress of colonizing microorganisms comprised of
gram-positive, gram-negative and anaerobic organisms, from the mouth to the systemic
circulation causing life-threatening sepsis. As well with ulceration, products from colonizing
bacteria invade into the submucosal tissue. This triggered macrophages, leading to additional
production of the proinflammatory cytokines TNF-, IL-1 and IL-6. Injurious enzymes are
then produced by inflammatory cells that move to the base of the ulcerated tissue. Alterations
in the composition and quantity of saliva would seem influence the vulnerability of tissue to
cytotoxic agents and the tissue capability to heal. Finally, the results of ulceration are
additional cytokine amplification, inflammation, pain and the patient augmented risk for
bacteremia and sepsis.
Kstler and colleagues (2001) suggested that genetic polymorphisms in the expression of
transcription factors transforming this inflammatory reaction can clarify partially the
individual discrepancies in the severity of oral mucositis at this phase.
Healing
The extracellular matrix initiates the healing stage of oral mucositis by signaling a
regeneration of epithelial cell proliferation and differentiation. Local microbial flora is
reestablished and white cell counts return to normal (leukocyte recovery).
III.
BA
CK
GR
OU
ND
25
Fig
ure
3. A
Mul
tipl
e M
echa
nism
Mod
el o
f th
e P
atho
biol
ogy
of M
ucos
itis
(Ada
pted
fro
m S
onis
, 200
7)
III. BACKGROUND
26
Following the healing stage, the oral mucosa seems to be normal. Nevertheless, although its
normal appearance, the mucosal environment has been altered considerably, resulting to
cancer therapy remains, and there is residual angiogenesis, increasing the patient risk of oral
mucositis with subsequent courses of anticancer therapy. The process of tissue behavior must
be regulated to some degree by the type of cancer treatment (chemotherapy versus radiation
therapy), the agents selected and the dose and timing of therapy. In most cases, mucositis is an
acute phenomenon that is self-resolving once cancer therapy ends.
The concept of a genetic predisposition for mucotoxicity (related to cancer therapy) is well
established. Disparities in individual vulnerability to chemotherapy-induced and radiotherapy-
induced toxicities have been renowned for years and this evidence supports the hypothesis
expressed above. Furthermore, murine strains vary in their mucosal response to radiation.
Single nucleotide polymorphisms (SNPs) have been recognized that are linked with the
metabolism of an amount of chemotherapeutic agents. Those who express phenotypes that
result in insufficiency of enzymes required for metabolism of specific chemotherapy drugs are
at improved risk of toxicity. However, Anthony et al (2006) recounts that the number of
patients with such deficiencies is far too small to account for the incidence of toxicity. An
alternative approach is to inquire if genetic control of mucositis mediators could also take part
in determining risk and additional describes the distinctive mucosal response to challenge.
There is considerable direct and indirect information to propose that a variety of genetically
controlled factors have an effect on mucosal response to chemotherapy or radiation therapy.
These elements may mostly impact all mucosal tissue types, or they may be tissue specific,
such as trefoils and defensins. These findings, as well as results suggesting that the possibility
of toxicity is determined in part by gender or ethnicity, indubitably will be topics for added
investigation. If we could predict which patients were at high risk for mucositis by genetic
testing, their therapy could be deliberate accordingly.
A current study by Gibson and partners (2006) cited by Logan et al (2006) provided data on
morphological and ultra structural changes in the oral mucosa ensuing cytotoxic
chemotherapy. This study established that the level of apoptosis taking place in the oral
mucosa peaked at 3 days following chemotherapy and this was 400 times the level seen in the
healthy controls. Similarly ultra structural changes occurred in the mucosa and persisted up to
11 days following chemotherapy. Gibsons data support the 5 stage hypothesis of mucositis
pathogenesis in which transcription factors activated by cancer therapy or reactive oxygen
species play a foremost role in the biological cascade that leads to mucosal damage. In the
context of mucositis, the transcription factor NF-kB is considered to be one of the major
III. BACKGROUND
27
drivers of the condition. Its activation results in the upregulation of numerous genes and
subsequent production of pro-inflammatory cytokines including TNF-, interleukin-1 and
interleukin-6, which results in the improved tissue injure in all compartments of the mucosa,
not solely the epithelium. Additionally, NF-kB causes upregulation of COX-2 as well, which
has also been implicated in rising levels of matrix metalloproteinases, a probable mediator of
tissue damage. It is though that the following amplification of these biological events via
positive feedback loops, result in the extensive tissue damage seen in the clinical setting as
ulceration.
A study conducted by Logan and partners (2006) demonstrated that NF-kB and COX-2 were
elevated following chemotherapy even when histologically, there appeared to be little
dissimilarity between the pre- and post-chemotherapy appearance of the tissue. In the context
of cytotoxic chemotherapy still there are also confounding factors due to the action of the
drugs and their pharmacology. It has been revealed that 5-fluorouracil can suppress the
transcription factor NF-kB. Nevertheless, additional work needs to be done to establish the
effects of individual chemotherapeutic agents on the expression of these factors in patients
undergoing chemotherapy and their consequent role in the pathobiology of mucositis. Surely
COX-2 is up regulated by NF-kB and in addition to playing a significant role in inflammatory
pathways, it has also been demonstrated to contribute to tumor development by stimulating
angiogenesis. Consequently, it has been suggested that affected patients would be at improved
risk of oral mucositis through following treatment of their cancer.
Logan and partners (2007), in rodent model of irinotecan-induced mucosal damage, evaluated
tissue levels of NF-k, TNF, and Interleukins-1 and -6 using typical immunohistochemical
techniques. After the administration of irinotecan, buccal mucosa, jejunum and colon were
collected from rats and studied. Tissue levels of NF-k, TNF, and Interleukins-1 and -6
peaked between 2 and 6 hours in the tissues examined. These results supply additional data to
the crucial role of NF-k and associated cytokines in the pathogenesis of mucositis.
It is evident that mucositis is much more than just an epithelial event and this five-stage
model helps to provide a mechanistic understanding of the complex biology of mucositis
(Redding, 2005; Sonis et al, 2004). The global elements noted above describe the elementary
mucosal vulnerability to regimen-related damage by providing overlying conditions that
support or oppose injury. These conditions influence the tissue, cellular and molecular
response and, once the response takes place, the local tissue environment proceed as an
accelerator or attenuator. It is possible that the response of the ultimate mucositis target tissue
III. BACKGROUND
28
occurs just when a biological doorsill is accomplished through collective mechanisms that
strength apoptosis or a decrease of cell regeneration. During resolution of the damage, the
tissue reacts to further sequences of signals focused on healing and recovery. In this instance,
as well, global, tissue, cellular and molecular factors modulate and mediate the procedure
(Anthony et al, 2006).
E. PREDICTIVE FACTORS
Results from investigation performed over the past decade have transformed thinking
concerning the pathogenesis of mucositis from an original notion in which it was viewed as
basically the consequence of nonspecific epithelial clonogenic cell death to a more complex
pan-tissue process. Additionally, it has provided the basis for us to develop a hierarchical
characterization of those factors that establish the risk, rate of progression, and decisive
clinical response of the gastrointestinal mucosa to antineoplastic treatment (Anthony et al,
2006). Agreeing with Jaronesky (2006), knowing the risk factors for oral mucositis, the
circumstances that may intensify mucosal injury and the state of the oral cavity is solution to
performing good nursing assessments. Once cancer patients are admitted to a clinic or
hospital for chemotherapy, health providers should achieve meticulous histories and oral
assessments to recognize factors that enhance patients risk for developing oral mucositis
(Berger et al, 1998 cited by Jaronesky, 2006).
It is imperative that is becoming increasingly obvious, that the concepts developed about
mucositis, maybe the best studied regimen-related toxicity, are more broadly applicable to
other adverse side effects of cancer treatment. The risk and course of regimen-related mucosal
damage is expected to be determined no less than two levels: first, there are broad, global,
macroscopic factors (include components that are related to the patient and the treatment); and
second, there are molecular and cellular elements that may play specific mechanistic roles
(include biological controllers and mediators). Equally, these may be generic and nonspecific,
or they have exclusive functions and characteristics that are related to specific mucosal tissue
types (Anthony et al, 2006).
Furthermore, the capacity to predict which patients are at risk of mucositis might become
possible. However, individual variability in toxic mucosal response is almost impossible to
predict at present; but, this might change (Sonis, 2004).
III. BACKGROUND
29
Numerous factors, associated with cancer patient or his surrounding environment, appears to
increase the potential for developing oral mucositis after cancer therapies, such as
chemotherapy and radiotherapy, and these factors can be divided regarding to its modifiable
capacity.
The predictive factors not modifiable or particularly difficult to modify, described
subsequently, comprise: sex (Vokurka et al, 2006), age (Repetto, 2003), ethnicity (McCollum
et al, 2002), diabetes, sociodemographic data, salivary flow/xerostomia, regimen of cytotoxic
drugs, herpes simplex virus antibody titer (McCarthy et al, 1998), patients diagnosis (Pico et
al, 1998), and genetic polymorphisms in the expression of transcription factors transforming
the inflammatory reaction (IL-1, Il-6 e TNF-) (Kstler et al, 2001).
Age
Oral mucositis is influenced by patients age. However, there are contradictory data relating to
the effects of age and the development of chemotherapy-induced mucositis. Pico and
colleagues (1998) experienced that, usually, younger patients appear to have an increase risk
of mucositis associated with chemotherapy. This observation may be explained by the further
rapid epithelial mitotic rate or the existence of additional epidermal growth factor receptors in
the epithelium of younger patients. As a result, younger patients develop mucositis more
commonly than older patients receiving equivalent type of treatment for analogous
malignancies. Once lesions develop, they heal more quickly in the younger population (Sonis,
1998; Kstler et al, 2001).
Hematologic malignancies are relatively more frequent in children than adults, and their
treatment tend to produce more prolonged and intense myelosuppression, which may also
result in more severe indirect mucotoxicity. Alternatively, the physiologic decline in renal
function associated with aging may result in older patients at higher risk of oral mucositis
related to chemotherapy (Pico et al, 1998). Age-related physiologic changes that can enhance
the toxicity of chemotherapy are decreased stem-cell reserves, decreased capacity to restore
cell damage, progressive loss of body protein, and accumulation of body fat. A decline in
organ function can change the pharmacokinetics, pharmacodynamics or pharmacogenetics of
various frequently used chemotherapeutic agents in some elderly patients, making toxicity
fewer expected. Comorbidities increase the risk of toxicity through their effects on the body.
III. BACKGROUND
30
Additionally, the drugs used to treat comorbidities may interrelate with citotoxic drugs,
potentially increasing toxicity in elderly patients (Repetto, 2003; Stein et al, 1995).
Agreeing to Brown (2004), cited by Jaronesky (2006), oral mucositis develops more
repeatedly among adults younger than 20 years of age, and individuals older than age 50 have
an improved possibility of developing oral mucositis that is harsh.
In a clinical trial (phase III), Stein and partners (1995) revealed that advanced age is an
independent risk factor for severe toxicity from 5-FU-based chemotherapy for advanced
colorectal cancer. Generally, the dose limiting toxicities of fluoropyrimidines are
gastrointestinal, but in this study, elderly patients normally experienced severe toxicity in
other sites, and age was an important risk factor for multiple-organ toxicities (Stein et al,
1995). Vokes and colleagues (1993), cited by Stein et al (1995), reported positive associations
among age and severe mucositis. The incidence of severe/very severe oral mucositis is higher
for patients age 65 or older than for those under age 65 (Sloan et al, 2000).
Gender
Patients gender is supposed to play a role in propensity of developing oral mucositis and this
role continues to be evaluated in clinical trials. In a study of 5-Fu-based treatment for
advanced colorectal cancer conducted by Stein and colleagues (1994), sex was an independent
predictor of severe toxicity. The clearance of infusional 5-Fu is lower in women, suggesting a
pharmacokinetic contribution to this observed toxicity pattern. The effects of age and sex
could be additive, as they may be based on different mechanisms of toxicity. In this analysis,
it was observed a devastating incidence of severe toxicity in elderly women. Prospective trials
with age and sex stratification will be necessary to determine the degree to which these are
independent risk factors for 5-Fu toxicity.
In a meta-analysis of six North Central Cancer Treatment Group (NCCTG) trials involving
patients receiving their first ever 5-Fu-based chemotherapy, Sloan and partners (2000)
revealed that women reported a higher incidence of oral mucositis for all six studies, with a
difference as much as 19% more than what was reported among men. Concerning to the
intensity of oral mucositis between sexes, the incidence of severe mucositis for women was
approximately double the rate observed for the men. So, womens mucositis scores and
incidence rates seem to be every time higher than those reported by men. The explanation for
this disparity is unknown at this point. One may consider an amount of hypotheses, including
III. BACKGROUND
31
differentials in stoicism, frailty, machismo, and biologic differences such as rates for
metabolism of 5-Fu. Nonetheless, none of these can be proven or disproven without
additional studies designed purposely to answer these subjects. In upcoming researches, the
use of sex as a critical stratification factor and/or covariate in the design of studies for oral
mucositis should be supported.
Sloan and colleagues (2002), in a semi-meta-analysis of the toxicity on 5-Fu-based studies
conducted by the NCCTG colorectal cancer program, observed that both men and women
experienced toxicity of some kind, but women experience more severe toxicity than men.
Individually, the incidence rates of toxicity are higher among women than men, and women
experienced 8% more oral mucositis. Additionally, the trial in which was noted the most
divergence between the incidences of oral mucositis by sex prescribed the uppermost dose of
5-Fu and leucoverin. Given the proof of a sex-dependent toxicity difference, it is rational to
search for elucidation for potential mechanisms. Milano et al (1999) cited by Sloan et al
(2002), reported a discrepancy in levels of dihydropyrimidine dehydrogenase (DPD) among
sexes, but the data are contradictory. DPD is the primary enzyme for 5-Fu clearance, and in
other studies (Harris et al, 1991 cited by Chansky et al, 2005) extreme deficiencies in this
enzyme have been associated with severe 5-Fu toxicity in both men and women. It has been
postulated that the differences in toxicity profiles across sexes might be related to thymidylate
synthase levels (Ito et al, 2000; Cascinu et al, 1999 cited by Sloan et al, 2002). Nevertheless,
there is no report of sex differences in thymidylate synthase levels. A crucial question takes
place concerning the relationship between toxicity incidence and treatment efficacy. We do
not know whether the increasing toxicity is related to increasing death rates. It could be
argued that the improved toxicity in women means that they are receiving an upper biologic
dose of antitumor therapy, which could imply an enhanced cure rate or a higher possibility of
response. In opposition, if the toxicity causes extreme dose reductions, it could be argued that
women are receiving a lower real dose and consequently receiving suboptimal treatment.
Additional research efforts are essential to attend to this question (Sloan et al, 2002).
In a study for gender differences in specific aspects of 5-Fu toxicity that persist across a
variety of treatment regimens for colorectal carcinoma, conducted by Chansky and partners
(2005), 5-Fu toxicity has been more severe in women than in men, particularly with respect to
hematologic toxicities and mucositis. In addition, it was supported that women experience
higher maximum toxicity grades, an improved number of toxicity types, and harsher moderate
to severe mucositis compared with men, resembling the other studies described above.
III. BACKGROUND
32
Reduction of toxicity may be above all a quality of life issue, but it is possible that a decrease
in 5-Fu toxicity among women could lead to enhanced survival.
Diabetes Mellitus/Type 2
Type II diabetes mellitus is associated with an increased risk of colorectal cancer
(approximately 30%), on the basis of chronic hyperinsulinemia and hyperglycemia. The risk
increase is present in both sexes, as well as in both colonic and rectal cancers (Yang et al,
2005; Larsson et al, 2005).
In a clinical trial of adjuvant chemotherapy to examine the effect of diabetes mellitus on long-
term outcomes after primary surgical treatment of high-risk stage II and stage III colon cancer
conducted by Meyerhardt and partners (2003), patients with diabetes had significantly worse
5-year disease-free survival, 5-year recurrence-free survival and overall survival compared
with patients without diabetes. So, diabetes mellitus is associated with an augmented risk of
mortality and cancer recurrence. Concerning to treatment-related toxicity there were no
considerable differences in rates of severe nausea, vomiting, stomatitis, leukopenia, fever, and
infection between patients with or without diabetes. However, patients with diabetes mellitus
did experience a moderately higher rate of severe treatment-related diarrhea. Nonetheless,
patients with diabetes tolerate adjuvant ch